4.1 introduction 4.2 virtual circuit and datagram networks 4.3 what ’ s inside a router

4.1 introduction 4.2 virtual circuit and datagram networks 4.3 what’s inside a router 4.4 IP: Internet Protocol datagram format IPv4 addressing ICMP IPv6 4.5 routing algorithms link state distance vector hierarchical routing 4.6 routing in the Internet RIP OSPF BGP 4.7 broadcast and multicast routing Chapter 4: outline Network Layer

used by hosts & routers to communicate network-level information error reporting: unreachable host, network, port, protocol echo request/reply (used by ping) Part of network-layer, but “above”IP: ICMP messages are carried in IP datagrams (see RFC 792) ICMP message: type, code plus IP header and at least the first 8 bytes of data field from the original IP datagram (typ. TCP or UDP header) ICMP: internet control message protocol TypeCodedescription 0 0 echo reply (to ping) 3 0 dest. network unreachable 3 1 dest. protocol unreachable 3 3 dest. port unreachable 3 6 dest. network unknown 3 7 dest. host unknown 4 0 source quench (congestion control - not used) 8 0 echo request (ping) 9 0 route advertisement 10 0 router discovery 11 0 TTL expired 12 0 bad IP header Network Layer

source sends series of UDP segments to destination first set of 3 has TTL =1 second set has TTL=2, etc. unlikely port number when nth set of datagrams arrives to nth router: router discards datagrams and sends source ICMP messages (type 11, code 0) ICMP messages includes name of router & IP address when ICMP messages arrives, the source records RTTs Traceroute and ICMP stopping criteria: • UDP segment eventually arrives at destination host • destination returns ICMP “port unreachable” message (type 3, code 3) • source stops 3 probes 3 probes 3 probes Network Layer

IPv6: motivation • History: first defined as IPv4 predecessor in early-1990’s • current definition: RFC 2460, December 1998 • Initial motivation:32-bit address space soon to be completely allocated. • last block of IPv4 addresses was allocated by IANA in February 2011 • Additional motivation: • header format helps speed processing/forwarding • header changes to facilitate QoSextensions • IPv6 datagram format: • fixed-length 40 byte header • no options field, no IP checksum • no fragmentation allowed in network core (only at source) Network Layer

IPv6 datagram format priority: identify priority among datagrams in flow flow Label: identify datagrams in same “flow”(concept of“flow” not currently well defined). next header: identify upper layer protocol for data class ver flow label Used for QoS extensions Possible address range: 3.4 x 1038. hop limit payload len next hdr source address (128 bits) Represented as eight groups of four hexadecimal digits separated by colons destination address (128 bits) Used like IPv4 protocol field data 32 bits Network Layer

Other changes from IPv4 • checksum:removed entirely to reduce processing time at each hop • options: allowed, but outside of header, indicated by “Next Header” field • ICMPv6: new version of ICMP (RFC 4443) • additional message types, e.g. “Packet Too Big” • multicast group management functions (replaces IGMP) Network Layer

IPv6 header fields IPv6 source dest. address UDP/TCP payload IPv4 payload Transition from IPv4 to IPv6 • not all routers can be upgraded simultaneously • no mass conversion(“All together, now!”) • how will the network operate with mixed IPv4 and IPv6 routers? (see RFC 4213) • tunneling: IPv6 datagram carried as payload in IPv4 datagram among IPv4 routers IPv4 header fields IPv4 source, dest. address IPv6 datagram IPv4 datagram Network Layer

IPv4 tunnel connecting IPv6 routers logical view: A A E E B B F F IPv6 IPv6 IPv6 IPv6 IPv6 IPv6 IPv6 IPv6 Tunneling C D physical view: IPv4 IPv4 Network Layer

Flow: X Src: A Dest: F data Flow: X Src: A Dest: F data IPv4 tunnel connecting IPv6 routers logical view: A A E E B B F F IPv6 IPv6 IPv6 IPv6 IPv6 IPv6 IPv6 IPv6 src:B dest: E src:B dest: E flow: X src: A dest: F data flow: X src: A dest: F data A-to-B: IPv6 E-to-F: IPv6 B-to-C: IPv6 inside IPv4 B-to-C: IPv6 inside IPv4 Tunneling C D physical view: IPv4 IPv4 Network Layer

routing algorithm determines end-end-path through network forwarding table is constructed based on routing algorithm results and specifies local forwarding at this router 1 3 2 Interplay between routing, forwarding routing algorithm local forwarding table dest address output link address-range 1 address-range 2 address-range 3 address-range 4 3 2 2 1 IP destination address in arriving packet’s header Network Layer

5 3 5 2 2 1 3 1 2 1 z x w u y v Graph abstraction graph: G = (N,E) N: nodes E: edges N = set of routers = { u, v, w, x, y, z } E = set of physical links ={ (u,v), (u,x), (v,x), (v,w), (x,w), (x,y), (w,y), (w,z), (y,z) } Network Layer

5 3 5 2 2 1 3 1 2 1 z x w u v y Graph abstraction: costs NOTES: 1) c(x,x’) = cost of link (x,x’) e.g., c(w,z) = 5 2) cost between pair not in E =  e.g. c(u,z) =  3) a node is said to be a neighbor of another if the pair is in E e.g. x, v and w are neighbors of u cost of path (x1, x2, x3,…, xp) = c(x1,x2) + c(x2,x3) + … + c(xp-1,xp) question: what is the least-cost path between u and z ? routing algorithm: algorithm that finds that least cost path Network Layer

5 3 5 2 2 1 3 1 2 1 z x w u v y Graph abstraction: costs cost could always be 1, or inversely related to bandwidth, or inversely related to congestion cost of path (x1, x2, x3,…, xp) = c(x1,x2) + c(x2,x3) + … + c(xp-1,xp) • Note: network costs for a given link can be based on various factors such as: • geographic distance/physical length of link • traffic loading/congestion • transit time, speed of link • link access cost, usage fees • etc. Network Layer

Scope: global or decentralized information? global: all routers have complete topology, link cost info link information broadcast “link state” algorithms decentralized: router knows physically-connected neighbors, link costs to neighbors iterative process of computation, exchange of info with neighbors “distance vector” algorithms Persistence: static or dynamic? static: routes change slowly, infrequently over time dynamic: routes change more quickly periodic updates in response to link cost changes Routing algorithm classification Network Layer

Dijkstra’s algorithm net topology, link costs known to all nodes accomplished via “link state broadcast” all nodes have same info computes least cost paths from one node (“source”) to all other nodes calculates forwarding table for that node iterative: after k iterations, know least cost path to k destinations notation: c(x,y): link cost from node x to y; = ∞ if not direct neighbors D(v): current value of cost of path from source to dest. v p(v): predecessor node along path from source to v N': set of nodes whose least cost path definitively known A Link-State Routing Algorithm Network Layer

Dijsktra’s Algorithm 1 Initialization: 2 N' = {u} 3 for all nodes v 4 if v adjacent to u 5 then D(v) = c(u,v) 6 else D(v) = ∞ 7 8 Loop 9 find w not in N' such that D(w) is a minimum 10 add w to N' 11 update D(v) for all v adjacent to w and not in N' : 12 D(v) = min( D(v), D(w) + c(w,v) ) 13 /* new cost to v is either old cost to v or known 14 shortest path cost to w plus cost from w to v */ 15 until all nodes in N' Network Layer

Dijkstra’s algorithm: example 9 11,w 14,x 11,w ∞ ∞ ∞ 3,u 5,u 5,u 6,w 6,w 7,u 7 5 4 8 3 w u x v y z 2 3 4 7 10,v 14,x D(v) p(v) D(w) p(w) D(x) p(x) D(y) p(y) D(z) p(z) Step N' u 0 uw 1 uwx 2 uwxv 3 uwxvy 4 12,y uwxvyz 5 notes: • construct shortest path tree by tracing predecessor nodes • ties can exist (can be broken arbitrarily) Network Layer

5 3 5 2 2 1 3 1 2 1 z x w u v y Dijkstra’s algorithm: another example D(v),p(v) 2,u 2,u 2,u D(x),p(x) 1,u D(w),p(w) 5,u 4,x 3,y 3,y D(y),p(y) ∞ 2,x Step 0 1 2 3 4 5 N' u ux uxy uxyv uxyvw uxyvwz D(z),p(z) ∞ ∞ 4,y 4,y 4,y Network Layer

z x w u y v destination link (u,v) v (u,x) x y (u,x) (u,x) w z (u,x) Dijkstra’s algorithm: example (2) resulting shortest-path tree from u: resulting forwarding table in u: Network Layer

algorithm complexity:n nodes each iteration: need to check all nodes, w, not in N n(n+1)/2 comparisons: O(n2) more efficient implementations possible: O(nlogn) oscillations possible: e.g., support link cost equals amount of carried traffic: 2+e 0 0 0 1 1+e C C C C D D D D B B A B B A A A 2+e 2+e 0 0 1 1 1+e 1+e 0 0 0 0 given these costs, find new routing…. resulting in new costs given these costs, find new routing…. resulting in new costs given these costs, find new routing…. resulting in new costs Dijkstra’s algorithm, discussion 1 1+e 0 0 e 0 1 1 e initially Network Layer

Distance vector algorithm Bellman-Ford equation (dynamic programming) let dx(y) := cost of least-cost path from x to y then dx(y) = min {c(x,v) + dv(y) } v cost from neighbor v to destination y cost to neighbor v min taken over all neighbors v of x Network Layer

5 3 5 2 2 1 3 1 2 1 z x w u v y Bellman-Ford example clearly, dv(z) = 5, dx(z) = 3, dw(z) = 3 B-F equation says: du(z) = min { c(u,v) + dv(z), c(u,x) + dx(z), c(u,w) + dw(z) } = min {2 + 5, 1 + 3, 5 + 3} = 4 node achieving minimum is next hop in shortest path, used inforwarding table Network Layer

Distance vector algorithm • Dx(y) = estimate of least cost from x to y • x maintains distance vector Dx = [Dx(y): y є N ] • node x: • knows cost to each neighbor v: c(x,v) • maintains its neighbors’ distance vectors. For each neighbor v, x maintains Dv = [Dv(y): y є N ] Network Layer

Distance vector algorithm key idea: • from time-to-time, each node sends its own distance vector estimate to neighbors • when x receives new DV estimate from neighbor, it updates its own DV using B-F equation: Dx(y) ← minv{c(x,v) + Dv(y)} for each node y ∊ N • under minor, natural conditions, the estimate Dx(y) converges to the actual least cost dx(y) Network Layer

iterative, asynchronous:each local iteration caused by: local link cost change DV update message from neighbor distributed: each node notifies neighbors only when its DV changes neighbors then notify their neighbors if necessary Distance vector algorithm each node: waitfor (change in local link cost or msg from neighbor) recompute estimates if DV to any dest has changed, notify neighbors Network Layer

2 1 7 z y x Dx(z) = min{c(x,y) + Dy(z), c(x,z) + Dz(z)} = min{2+1 , 7+0} = 3 Dx(y) = min{c(x,y) + Dy(y), c(x,z) + Dz(y)} = min{2+0 , 7+1} = 2 node x table cost to cost to x y z x y z x 0 2 7 x 0 3 2 y y 2 0 1 from ∞ ∞ ∞ from z z 7 1 0 ∞ ∞ ∞ node y table cost to x y z x ∞ ∞ ∞ 2 0 1 y from z ∞ ∞ ∞ node z table cost to x y z x ∞ ∞ ∞ y from ∞ ∞ ∞ z 7 1 0 time Network Layer

2 1 7 z y x Dx(z) = min{c(x,y) + Dy(z), c(x,z) + Dz(z)} = min{2+1 , 7+0} = 3 Dx(y) = min{c(x,y) + Dy(y), c(x,z) + Dz(y)} = min{2+0 , 7+1} = 2 node x table cost to cost to cost to x y z x y z x y z x 0 2 7 x 0 3 2 x 0 2 3 y y 2 0 1 from ∞ ∞ ∞ y from 2 0 1 from z z 7 1 0 ∞ ∞ ∞ z 3 1 0 node y table cost to cost to cost to x y z x y z x y z x ∞ ∞ x 0 2 7 ∞ 2 0 1 x 0 2 3 y y 2 0 1 y from from 2 0 1 from z z ∞ ∞ ∞ 7 1 0 z 3 1 0 cost to cost to node z table cost to x y z x y z x y z x 0 2 7 x 0 2 3 x ∞ ∞ ∞ y y 2 0 1 from y 2 0 1 from from ∞ ∞ ∞ z z z 3 1 0 3 1 0 7 1 0 time time Network Layer

1 4 1 50 x z y Distance vector: link cost changes link cost changes: • node detects local link cost change • updates routing info, recalculates distance vector • if DV changes, notify neighbors t0 : y detects link-cost change, updates its DV, informs its neighbors. “good news travels fast” t1 : z receives update from y, updates its table, computes new least cost to x , sends its neighbors its DV. t2 : y receives z’s update, updates its distance table. y’s least costs do not change, so y does not send a message to z. Network Layer

60 4 1 50 x z y Distance vector: link cost changes link cost changes: • node detects local link cost change • bad news travels slow - “count to infinity” problem! • 44 iterations before algorithm stabilizes: see text poisoned reverse: • If Z routes through Y to get to X : • Z tells Y its (Z’s) distance to X is infinite (so Y won’t route to X via Z) • will this completely solve count to infinity problem? Network Layer

message complexity LS: with n nodes, E links, O(nE) msgs sent DV:exchange between neighbors only convergence time varies speed of convergence LS: O(n2) algorithm requires O(nE) msgs may have oscillations DV: convergence time varies may be routing loops count-to-infinity problem robustness: what happens if router malfunctions? LS: node can advertise incorrect link cost each node computes only its own table DV: DV node can advertise incorrect path cost each node’s table used by others error propagate thru network Comparison of LS and DV algorithms Network Layer

scale: with 600 million destinations: can’t store all destinations in routing tables! routing table exchange would swamp links! administrative autonomy internet = network of networks each network admin may want to control routing in its own network Hierarchical routing our routing study thus far - idealization • all routers identical • network “flat” … not true in practice Network Layer

aggregate routers into regions,“autonomous systems” (AS) routers in same AS run same routing protocol “intra-AS” routing protocol routers in different AS can run different intra-AS routing protocol gateway router: at “edge” of its own AS has link to router in another AS Hierarchical routing Network Layer

forwarding table configured by both intra- and inter-AS routing algorithm intra-AS sets entries for internal dests inter-AS & intra-AS sets entries for external dests 3a 3b 2a AS3 AS2 1a 2c AS1 2b 1b 1d 3c 1c Inter-AS Routing algorithm Intra-AS Routing algorithm Forwarding table Interconnected ASes Network Layer

suppose router in AS1 receives datagram destined outside of AS1: router should forward packet to gateway router, but which one? AS1 must: learn which dests are reachable through AS2, which through AS3 propagate this reachability info to all routers in AS1 job of inter-AS routing! 2c 2b 1b 1d 3c 1c 3a 3b 2a 1a AS1 Inter-AS tasks AS3 other networks other networks AS2 Network Layer

2c 2b 1b 1d 1c 3c 3a 3b 2a 1a AS1 Example: setting forwarding table in router 1d • suppose AS1 learns (via inter-AS protocol) that subnet xis reachable via AS3 (gateway 1c), but not via AS2 • inter-AS protocol propagates reachability info to all internal routers • router 1d determines from intra-AS routing info that its interface I is on the least cost path to 1c • installs forwarding table entry (x,I) … x AS3 other networks other networks AS2 Network Layer

2c 2b 1b 1d 1c 3c 3a 3b 2a 1a AS1 Example: choosing among multiple ASes • now suppose AS1 learns from inter-AS protocol that subnet x is reachable from AS3 and from AS2. • to configure forwarding table, router 1d must determine which gateway it should forward packets towards for dest x • this is also job of inter-AS routing protocol! … x …… AS3 other networks other networks AS2 ? Network Layer

Example: choosing among multiple ASes • now suppose AS1 learns from inter-AS protocol that subnet xis reachable from AS3 and from AS2. • to configure forwarding table, router 1d must determine towards which gateway it should forward packets for destx • this is also job of inter-AS routing protocol! • hot potato routing: send packet towards closest of two routers. determine from forwarding table the interface I that leads to least-cost gateway. Enter (x,I) in forwarding table use routing info from intra-AS protocol to determine costs of least-cost paths to each of the gateways learn from inter-AS protocol that subnet x is reachable via multiple gateways hot potato routing: choose the gateway that has the smallest least cost Network Layer

Intra-AS Routing • also known as interior gateway protocols (IGP) • most common intra-AS routing protocols: • RIP: Routing Information Protocol • OSPF: Open Shortest Path First • IGRP: Interior Gateway Routing Protocol (Cisco proprietary) Network Layer

u v w x z y C B D A RIP ( Routing Information Protocol) • included in BSD-UNIX distribution in 1982 • distance vector algorithm • distance metric: # hops (max = 15 hops), each link has cost 1 • DVs exchanged with neighbors every 30 sec in response message (aka advertisement) • each advertisement: list of up to 25 destination subnets(in IP addressing sense) from router A to destinationsubnets: subnethops u 1 v 2 w 2 x 3 y 3 z 2 Network Layer

RIP: example z y w x B D A C routing table in router D destination subnet next router # hops to dest w A 2 y B 2 z B 7 x -- 1 …. …. .... Network Layer

A-to-D advertisement dest next hops w - 1 x - 1 z C 4 …. … ... A 5 RIP: example z y w x B D A C routing table in router D destination subnet next router # hops to dest w A 2 y B 2 z B 7 x -- 1 …. …. .... Network Layer

RIP: link failure, recovery if no advertisement heard after 180 sec --> neighbor/link declared dead • routes via neighbor invalidated • new advertisements sent to neighbors • neighbors in turn send out new advertisements (if tables changed) • link failure info quickly (?) propagates to entire net • poison reverse used to prevent ping-pong loops (infinite distance = 16 hops) Network Layer

routed routed RIP table processing • RIP routing tables managed by application-level process called route-d (daemon) • advertisements sent in UDP packets (port 520), periodically repeated transport (UDP) transprt (UDP) network forwarding (IP) table network (IP) forwarding table link link physical physical Network Layer

4.1 introduction 4.2 virtual circuit and datagram networks 4.3 what ’ s inside a router

4.1 introduction 4.2 virtual circuit and datagram networks 4.3 what ’ s inside a router

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